Role of determinants of cadmium sensitivity in the tolerance of Schizosaccharomyces pombe to cisplatin

The genetic mechanisms underlying cisplatin (DDP) resistance in yeast were investigated by examining the cytotoxicity of DDP to Schizosaccharomyces pombe mutants that were either hypersensitive or resistant to Cd. Despite reports that have linked glutathione (GSH) to DDP resistance in human cancer cells, we found that a mutant of S. pombe that was hypersensitive to Cd by virtue of a 15-fold reduction in GSH level and lack of phytochelatin production was as tolerant as the wild-type strain to DDP. A mutant that harbored a mutation in hmt1, the gene encoding an ATP-binding cassette-type transporter for vacuolar sequestration of a phytochelatin/Cd complex, exhibited only mild hypersensitivity to DDP even though it was 100-fold more sensitive to Cd. Overexpression of hmt1 in wild-type or mutant cells conferred tolerance to Cd but failed to do the same for DDP. However, a strain that produced 6-fold more sulfide than wild-type cells was found to be 6-fold more resistant to DDP and twice as resistant to Cd; an association between DDP resistance and sulfide production was observed in three other strains that were examined, and overproduction of sulfide was accompanied by reduced platination of DNA. These results indicate that GSH and the GSH-derived phytochelatin peptides do not play critical roles in determining sensitivity to DDP in S. pombe but rather identify increased production of sulfide as a possible new mechanism of DDP resistance that may also be relevant to human cells.

Calcium- and zinc-binding proteins in intracellular transport

The complex mechanism of intracellular transport is regulated by free calcium in different manners. Calcium binding proteins regulate several aspects of the vesicle fusion mechanism mediated by NSF (N-ethylmaleimide sensitive fusion factor). At least in some regulated exocytosis, calcium-binding proteins are the trigger for fusion downstream of NSF, Still, calcium-binding proteins, such as annexins, may be part of a different fusion mechanism mediating some specific transport steps or working in parallel to the NSF-dependent fusion process. Calcium is not the only ion necessary for the function of factors involved in vesicular transport. A zinc requirement has been also proposed. One of the zinc-dependent factors is probably a protein with a cysteine-rich region that coordinates zinc and binds phorbol esters. Although protein kinase C is the more prominent family of proteins carrying this domain, the factor necessary for transport does not appear to function as a kinase.

Protein dimerization between Lmo2 (Rbtn2) and Tal1 alters thymocyte development and potentiates T cell tumorigenesis in transgenic mice

The LMO2 and TAL1 genes were first identified via chromosomal translocations and later found to encode proteins that interact during normal erythroid development. Some T cell leukaemia patients have chromosomal abnormalities involving both genes, implying that LMO2 and TAL1 act synergistically to promote tumorigenesis after their inappropriate co-expression. To test this hypothesis, transgenic mice were made which co-express Lmo2 and Tal1 genes in T cells. Dimers of Lmo2 and Tal1 proteins were formed in thymocytes of double but not single transgenic mice. Furthermore, thymuses of double transgenic mice were almost completely populated by immature T cells from birth, and these mice develop T cell tumours approximately 3 months earlier than those with only the Lmo2 transgene. Thus interaction between these two proteins can alter T cell development and potentiate tumorigenesis. The data also provide formal proof that TAL1 is an oncogene, apparently acting as a tumour promoter in this system.

Formation of the peroxisome lumen is abolished by loss of Pichia pastoris Pas7p, a zinc-binding integral membrane protein of the peroxisome

We have cloned and sequenced PAS7, a gene required for peroxisome assembly in the yeast Pichia pastoris. The product of this gene, Pas7p, is a member of the C3HC4 superfamily of zinc-binding proteins. Point mutations that alter conserved residues of the C3HC4 motif abolish PAS7 activity and reduce zinc binding, suggesting that Pas7p binds zinc in vivo and that zinc binding is essential for PAS7 function. As with most pas mutants, pas7 cells exhibit a pronounced deficiency in import of peroxisomal matrix proteins that contain either the type 1 peroxisomal targeting signal (PTS1) or the type 2 PTS (PTS2). However, while other yeast and mammalian pas mutants accumulate ovoid, vesicular peroxisomal intermediates, loss of Pas7p leads to accumulation of membrane sheets and vesicles which lack a recognizable lumen. Thus, Pas7p appears to be essential for protein translocation into peroxisomes as well as formation of the lumen of the organelle. Consistent with these data, we find that Pas7p is an integral peroxisomal membrane protein which is entirely resistant to exogenous protease and thus appears to reside completely within the peroxisome. Our observations suggest that the function of Pas7p defines a previously unrecognized step in peroxisome assembly: formation of the peroxisome lumen. Furthermore, because the peroxisomal intermediates in the pas7 delta mutant proliferate in response to peroxisome-inducing environmental conditions, we conclude that Pas7p is not required for peroxisome proliferation.

The oncogenic LIM protein Rbtn2 causes thymic developmental aberrations that precede malignancy in transgenic mice

RBTN2 is activated by the chromosomal translocation t(11;14) (P13;p11) in some T cell leukaemias. Histologically similar T cell tumours develop with long latency in transgenic mice when either CD2 or thy1.1 promoters control rbtn2 expression. During the asymptomatic period, perturbation of T cell differentiation occurs in the thymus. The major anomalies present during this phase are an increase in the percentage of large thymocytes lacking CD4 and CD8 markers and also of small thymocytes express both the T cell marker CD3 and the B cell-specific form of CD45. These abnormal T cell populations can be clonal and thus a primary result of aberrant expression of the LIM-protein Rbtn2 is alteration of T cell differentiation preceding overt malignancy. These data provide a biological explanation for the role of Rbtn2 in tumorigenesis and presumably RBTN2 expression in T cells after the translocation t(11;14) in children has the same effect.

Potential contraceptive use of epididymal proteins: evidence for the participation of specific antibodies against rat epididymal protein DE in male and female fertility inhibition

Previous studies in our laboratory indicated that immunization of male and female Wistar and Lewis rats with epididymal protein DE, resulted in the development of anti-DE antibodies in over 90% of the animals, with a significant and reversible reduction of fertility. In the present study, ELISA assays performed to analyze the evolution of the immune response indicated that antibody levels in the sera of immunized animals reached a maximum at 8 weeks after the initial injection and then gradually decreased, returning to control values by the end of the sixth month. Western blot experiments demonstrated that the immune sera specifically recognized DE in epididymal sperm extracts and epididymal cytosol, while no reaction was observed with different reproductive and essential organs. The immune sera were also capable of recognizing DE on the surface of both fresh and capacitated sperm as indicated by indirect immunofluorescence experiments. Finally, the exposure of sperm to immune sera prior to uterine insemination resulted in a significant (P < 0.05) reduction in the percentage of fertilized eggs compared to controls, with no effect on sperm motility and viability, nor on their ability to undergo capacitation. Together, these results support the participation of the raised antibodies as mediators of the antifertility effect and suggest a specific interference at the sperm-egg interaction level.

The oncogenic cysteine-rich LIM domain protein rbtn2 is essential for erythroid development

The LIM domain protein rbtn2 is associated with T cell acute leukemias. We demonstrate that rbtn2 is a nuclear protein expressed in the erythroid lineage in vivo, and using homologous recombination, we show that it is essential for erythroid development in mice. The homozygous rbtn2 null mutation leads to failure of yolk sac erythropoiesis and embryonic lethality around E10.5. Moreover, in vitro differentiation of yolk sac tissue from homozygous mutant mice and sequentially targeted double-mutant ES cells demonstrates a block to erythroid development. This shows a pivotal role for a LIM domain protein in lineage specification during mammalian development and suggests that RBTN2 and GATA-1 are critical at similar stages of erythroid differentiation.

LIM domain proteins in leukaemia and development

T cell acute leukaemias involve a number of different classes of oncogenes. A group of such genes is the RBTN family located on chromosomes 11 and 12. Two members of this family, RBTN1/Ttg-1 and RBTN2/Ttg-2, are located near recurring T cell acute lymphocytic leukaemia-associated translocations. Chromosomal translocations to both RBTN1/Ttg-1 and RBTN2/Ttg-2 involve T cell receptor (TCR) genes as result of an erroneous V(D)J joining process. RBTN1/Ttg-1 and RBTN2/Ttg-2 encode related proteins consisting of two cysteine-rich regions called LIM domains. The fact that LIM domains can be found with or without associated homeodomain led to the suggestion that the LIM domains may function as regulators of transcription, and that alterations of transcription networks, after chromosomal translocations, lead to leukaemia. This is a common feature that has been noted in the activation of transcription factors with a variety of structural motifs that include the basic helix-loop-helix motif and the homeodomain in leukaemias.

Mechanism of action of biological antioxidants

More and more diseases have been proposed to have a radical or oxidant involvement. Although in most cases we do not know if this involvement is a cause or a result of the disease process, it is still valuable to learn about those compounds or enzymes that might block, inhibit, or prevent radical-initiated reactions. Therefore, it becomes increasingly important to understand which compounds can function as antioxidants, where they are located in the body, and what their mechanism of action might be. As we increase our knowledge in these areas, we will have a better opportunity to propose interventions that might suppress or even reverse some of the ravages of oxidant-based diseases in humans.

Hydrolysis of phosphate monoesters: a biological problem with multiple chemical solutions

Formation of phosphate esters by kinases has long been recognized as an important process in biochemistry, but the reverse reaction, hydrolysis of phosphate esters by phosphatases, has attracted less attention. Recent work suggests that phosphatases are as important as kinases in regulatory processes, and that they constitute a diverse group of enzymes that utilize a variety of chemical means to accelerate phosphate ester hydrolysis.

The C6 zinc finger and adjacent amino acids determine DNA-binding specificity and affinity in the yeast activator proteins LAC9 and PPR1

LAC9 is a DNA-binding protein that regulates transcription of the lactose-galactose regulon in Kluyveromyces lactis. The DNA-binding domain is composed of a zinc finger and nearby amino acids (M. M. Witte and R. C. Dickson, Mol. Cell. Biol. 8:3726-3733, 1988). The single zinc finger appears to be structurally related to the zinc finger of many other fungal transcription activator proteins that contain positively charged residues and six conserved cysteines with the general form Cys-Xaa2-Cys-Xaa6-Cys-Xaa6-9-Cys-Xaa2-Cys-Xaa 6-Cys, where Xaan indicates a stretch of the indicated number of any amino acids (R. M. Evans and S. M. Hollenberg, Cell 52:1-3, 1988). The function(s) of the zinc finger and other amino acids in DNA-binding remains unclear. To determine which portion of the LAC9 DNA-binding domain mediates sequence recognition, we replaced the C6 zinc finger, amino acids adjacent to the carboxyl side of the zinc finger, or both with the analogous region from the Saccharomyces cerevisiae PPR1 or LEU3 protein. A chimeric LAC9 protein, LAC9(PPR1 34-61), carrying only the PPR1 zinc finger, retained the DNA-binding specificity of LAC9. However, LAC9(PPR1 34-75), carrying the PPR1 zinc finger and 14 amino acids on the carboxyl side of the zinc finger, gained the DNA-binding specificity of PPR1, indicating that these 14 amino acids are necessary for specific DNA binding. Our data show that C6 fingers can substitute for each other and allow DNA binding, but binding affinity is reduced. Thus, in a qualitative sense C6 fingers perform a similar function(s). However, the high-affinity binding required by natural C6 finger proteins demands a unique C6 finger with a specific amino acid sequence. This requirement may reflect conformational constraints, including interactions between the C6 finger and the carboxyl-adjacent amino acids; alternatively or in addition, it may indicate that unique, nonconserved amino acid residues in zinc fingers make sequence-specifying or stabilizing contacts with DNA.

The candidate Wilms' tumour gene is involved in genitourinary development

Wilms' tumour is an embryonic kidney tumour thought to arise through aberrant mesenchymal stem cell differentiation and to result from loss of function of a 'tumour suppressor' gene(s). Both sporadic and syndrome-associated Wilms' tumours are accompanied by an increased frequency of abnormalities of the urinary tract and genitalia. Deletional analysis of individuals with the WAGR syndrome (for, Wilms' tumour, aniridia, genitourinary abnormalities and mental retardation) showed that a Wilms' tumour gene lies at chromosomal position 11p13. This led to the isolation of a candidate Wilms' tumour gene, encoding a zinc-finger protein which is likely to be a transcription factor. To gain insight into the role of this candidate gene in normal development and tumorigenesis, we have now performed in situ messenger RNA hybridization on sections of human embryos and Wilms' tumours. The candidate Wilms' tumour gene is expressed specifically in the condensed mesenchyme, renal vesicle and glomerular epithelium of the developing kidney, in the related mesonephric glomeruli and in cells approximating these structures in tumours. The other main sites of expression are the genital ridge, fetal gonad and mesothelium. These data suggest that (1) this candidate is indeed a Wilms' tumour gene, (2) the associated genital abnormalities are pleiotropic effects of mutation in the Wilms' tumour gene itself, in support of recent genetic analysis, and (3) this gene has a specific role in kidney development and a wider role in mesenchymal-epithelial transitions.

brlA requires both zinc fingers to induce development

Expression of the Aspergillus nidulans brlA gene induces a developmental pathway leading to the production of asexual spores. We have introduced mutations into brlA that are expected to disrupt either or both Cys2-His2 Zn(II) coordination sites postulated to exist in the BrlA polypeptide. The resultant brlA alleles fail to induce either the asexual reproductive pathway or the expression of development-specific genes. These data support the hypothesis that brlA encodes a nucleic acid-binding protein whose activity requires each of two zinc fingers.

Steroid/thyroid receptor-like proteins with oncogenic potential: a review

Mutated or truncated forms of certain members of the steroid/thyroid receptor superfamily have oncogenic potential. The aberrant forms compete with the normal receptor for binding to the responsive element on the DNA and thus interfere negatively with the normal transcription control mechanism. Oncogenes that arise from dominant negative mutations may therefore be called "dononcs," to distinguish them from recessive types such as that causing retinoblastoma ("renoncs"). It is possible that dononcs are also responsible for the loss of hormonal responsiveness of some tumors during progression.

Intramolecular long-range electron transfer in the hemerythrin monomer: a pulse radiolysis study

The single sulfhydryl group (Cys-50) of the methemerythrin from Phascolosoma gouldii reacts with 5,5'dithiobis(2-nitrobenzoic acid) to form a mixed disulfide. The pulse radiolytically generated formate radical reduces this mixed disulfide to its radical anion. In turn, the disulfide radical anion reduces the protein two-iron center over a nominal distance of 13 A. The rate constant for this intramolecular electron transfer is approximately 15 s-1 at room temperature, pH 7. Between the two redox centers there is an equilibrium driving force of 0.78 V, measured by differential pulsed polarography.

Serendipity delta, a Drosophila zinc finger protein present in embryonic nuclei at the onset of zygotic gene transcription

Serendipity delta (sry delta) is a member of a set of Drosophila zinc finger protein genes showing maximal transcription during oogenesis. By using transformant lines, we monitored the zygotic expression of the sry delta gene and characterized some biochemical properties of a sry delta/beta-galactosidase fusion protein-containing fingers. Further analysis made use of anti-sry delta specific antibodies. During oogenesis, while sry delta mRNAs transcribed by nurse cells are transferred to the oocyte starting in stage 10, translation into protein occurs in the ooplasm starting in stage 12. The maternally inherited protein concentrates in embryonic nuclei during early cleavages, prior to the onset of zygotic transcription. At the blastoderm stage, the sry delta protein is localized in all somatic nuclei. Later in embryogenesis and up to the adult stage, the zygotic protein is present in nuclei of transcriptionally active cells (both somatic and germ line). These data are consistent with the sry delta protein being a transcription factor, with a role in zygotic activation of general cellular functions.

Spectroelectrochemical studies of the corrinoid/iron-sulfur protein involved in acetyl coenzyme A synthesis by Clostridium thermoaceticum

An 88-kDa corrinoid/iron-sulfur protein (C/Fe-SP) is the methyl carrier protein in the acetyl-CoA pathway of Clostridium thermoaceticum. In previous studies, it was found that this C/Fe-SP contains (5-methoxybenzimidazolyl)cobamide and a [4Fe-4S]2+/1+ center, both of which undergo redox cycling during catalysis, and that the benzimidazole base is uncoordinated to the cobalt (base off) in all three redox states, 3+, 2+, and 1+ [Ragsdale, S.W., Lindahl, P.A., & Münck, E. (1987) J. Biol. Chem. 262, 14289-14297]. In this paper, we have determined the midpoint reduction potentials for the metal centers in this C/Fe-SP by electron paramagnetic resonance and UV-visible spectroelectrochemical methods. The midpoint reduction potentials for the Co3+/2+ and the Co2+/1 couples of the corrinoid were found to be 300-350 and -504 mV (+/- 3 mV) in Tris-HCl at pH 7.6, respectively. We also removed the (5-methoxybenzimidazolyl)cobamide cofactor from the C/Fe-SP and determined that its Co3+/2+ reduction potential is 207 mV at pH 7.6. The midpoint potential for the [4Fe-4S]2+/1+ couple in the C/Fe-SP was determined to be -523 mV (+/- 5 mV). Removal of this cluster totally inactivates the protein; however, there is little effect of cluster removal on the midpoint potential of the Co2+/1+ couple. In addition, removal of the cobamide has an insignificant effect on the midpoint reduction potential of the [4Fe-4S] cluster. A 27-kDa corrinoid protein (CP) also was studied since it contains (5-methoxybenzimidazolyl)cobamide in the base-on form.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure-function relationships in the alpha subunit of Klebsiella pneumoniae nitrogenase MoFe protein from analysis of nifD mutants

Crude extracts of wild-type, nitrogenase-derepressed Klebsiella pneumoniae fractionated by nondenaturing gel electrophoresis contain, in addition to the major form of the MoFe protein, two minor variants of lower electrophoretic mobility. Of seven Nif- mutants of K. pneumoniae with nonpolar point mutations in nifD (encoding the alpha subunit of Kp1), three exhibit a wild-type-like electrophoretic pattern, whereas in the remaining four, the slowest-migrating form becomes the predominant species. Amino acid substitutions in mutants of the first type are located in the N terminus of NifD and include Gly-85 to Arg (UN1661), Glu-121 to Lys (UN1649), and Gly-161 to Asp (UN1683). Mutations of the second type are Gly-186 to Asp (UN1648), Gly-195 to Glu (UN1680), Ser-443 to Pro (UN1793), and Gly-455 to Asp (UN1650). Six of the mutated residues show interspecies conservation, three are close to conserved cysteines, and two are located next to conserved histidines. Based on evidence pointing to the possibility that the lowest-mobility form lacks the iron-molybdenum cofactor, these results provide insights into the functional significance of specific sites in the alpha subunit of the MoFe protein.