Identification of a mouse cDNA fragment whose expressed polypeptide reacts with anti-recA antibodies

Roles and regulatory mechanisms of KIN17 in cancers (Review)

KIN17, which is known as a DNA and RNA binding protein, is highly expressed in numerous types of human cancers and was discovered to participate in several vital cell behaviors, including DNA replication, damage repair, regulation of cell cycle and RNA processing. Furthermore, KIN17 is associated with cancer cell proliferation, migration, invasion and cell cycle regulation by regulating pathways including the p38 MAPK, NF-κB-Snail and TGF-β/Smad2 signaling pathways. In addition, knockdown of KIN17 was found to enhance the sensitivity of tumor cells to chemotherapeutic agents. Immunohistochemical analysis revealed that there were significant differences in the expression of KIN17 between cancer tissues and adjacent tissues. Both the Kaplan-Meier survival analysis and multivariate Cox regression analysis indicated that KIN17 is aberrantly high expressed in various tumor tissues and is also associated with poor prognosis in patients with various tumor types. Taken together, KIN17 has key roles in tumorigenesis and cancer development. Investigating the relationship between KIN17 and neoplasms will provide a vital theoretical basis for KIN17 to serve as a diagnostic and prognostic biomarker for cancer patients and as a potential target for cancer therapy.

1H, 15N, and 13C resonance assignments of the SH3-like tandem domain of human KIN protein

KIN is a DNA/RNA-binding protein conserved evolutionarily from yeast to humans and expressed ubiquitously in mammals. It is an essential nuclear protein involved in numerous cellular processes, such as DNA replication, class-switch recombination, cell cycle regulation, and response to UV or ionizing radiation-induced DNA damage. The C-terminal region of the human KIN (hKIN) protein is composed of an SH3-like tandem domain, which is crucial for the anti-proliferation effect of the full-length protein. Herein, we present the ¹H, ¹⁵N, and ¹³C resonances assignment of the backbone and side chains for the SH3-like tandem domain of the hKIN protein, as well as the secondary structure prediction based on the assigned chemical shifts using TALOS-N software. This work prepares the ground for future studies of RNA-binding and backbone dynamics.

Kin17 facilitates multiple double-strand break repair pathways that govern B cell class switching

Class switch recombination (CSR) in B cells requires the timely repair of DNA double-stranded breaks (DSBs) that result from lesions produced by activation-induced cytidine deaminase (AID). Through a genome-wide RNAi screen, we identified Kin17 as a gene potentially involved in the maintenance of CSR in murine B cells. In this study, we confirm a critical role for Kin17 in CSR independent of AID activity. Furthermore, we make evident that DSBs generated by AID or ionizing radiation require Kin17 for efficient repair and resolution. Our report shows that reduced Kin17 results in an elevated deletion frequency following AID mutational activity in the switch region. In addition, deficiency in Kin17 affects the functionality of multiple DSB repair pathways, namely homologous recombination, non-homologous end-joining, and alternative end-joining. This report demonstrates the importance of Kin17 as a critical factor that acts prior to the repair phase of DSB repair and is of bona fide importance for CSR.

DNA repair in neural cells: basic science and clinical implications

As one part of a distinguished scientific career, Dr. Bryn Bridges focused his attention on the issue of DNA damage and repair in stationary phase bacteria. His work in this area led to his interest in DNA repair and mutagenesis in another non-dividing cell population, the neurons in the mammalian nervous system. He has specifically taken an interest in the magnocellular neurons of the central nervous system, and the possibility that somatic mutations may be occurring in these neurons. As part of this special issue dedicated to Bryn Bridges upon his retirement, I will discuss the various DNA repair pathways known to be active in the nervous system. The importance of DNA repair to the nervous system is most graphically illustrated by the neurological abnormalities observed in patients with hereditary diseases associated with defects in DNA repair. I will consider the mechanisms underlying the neurological abnormalities observed in patients with four of these diseases: xeroderma pigmentosum (XP), Cockayne's syndrome (CS), ataxia telangectasia (AT) and AT-like disorder (ATLD). I will also propose a mechanism for one of the observations indicating that somatic mutation can occur in the magnocellular neurons of the aging rat brain. Finally, as a parallel to Bridges inquiry into how much DNA synthesis is going on in stationary phase bacteria, I will address the question of how much DNA synthesis in going on in neurons, and the implications of the answer to this question for recent studies of neurogenesis in adult mammals.

Identification of KIN (KIN17), a human gene encoding a nuclear DNA-binding protein, as a novel component of the TP53-independent response to ionizing radiation

Ionizing radiation elicits a genetic response in human cells that allows cell survival. The human KIN (also known as KIN17) gene encodes a 45-kDa nuclear DNA-binding protein that participates in the response to UVC radiation and is immunologically related to the bacterial RecA protein. We report for the first time that ionizing radiation and bleomycin, a radiomimetic drug, which produce single- and double-strand breaks, increased expression of KIN in human cells established from tumors, including MeWo melanoma, MCF7 breast adenocarcinoma, and ATM+ GM3657 lymphoblast cells. KIN expression increased rapidly in a dose-dependent manner after irradiation. Under the same conditions, several genes controlled by TP53 were induced with kinetics similar to that of KIN. Using the CDKN1A gene as a marker of TP53 responsiveness, we analyzed the up-regulation of KIN and showed that is independent of the status of TP53 and ATM. In contrast, the presence of a dominant mutant for activating transcription factor 2 (ATF2) completely abolished the up-regulation of KIN. Our results suggest a role for ATF2 in the TP53-independent increase in KIN expression after gamma irradiation.

Expression of Kin17 and 8-OxoG DNA glycosylase in cells of rodent and quail central nervous system

Kin17 and 8-Oxoguanine DNA glycosylase (Ogg1) are proteins, respectively, involved in illegitimate recombination and DNA repair in eukaryotic cells. To characterize the expression of these proteins in cell types of rodent and avian brains, we combined immunocytochemistry for either Kin17 or Ogg1 proteins with glial fibrillary acidic protein (GFAP, an astrocyte marker) immunodetection on the same tissue section. Both Kin17 and Ogg1 proteins were localized in cell nuclei and were extensively distributed in neuronal populations of quail and rodent brains. However, GFAP-immunoreactive cells were never labeled by Kin17 protein. This was observed in nerve fiber tracts, in the cerebral cortex, the hippocampal formation, the hypothalamic region, and the periventricular regions of the brain of both species studied. These results were confirmed by combining in situ hybridization of kin17 mRNA and GFAP immunodetection. On the contrary, GFAP-immunoreactive cells were often labeled by the Ogg1 protein in brain structures such as fiber tracts, the cortical surface, the cerebellum, and the ependymal surface of both quail and mouse brains. Our results suggest that the expression of the Kin17 protein (observed in neurons) and that of the Ogg1 protein (observed in neurons and glial cells) is conserved in brain phylogeny.

Intrinsic DNA bends: an organizer of local chromatin structure for transcription

DNA with a curved trajectory of its helix axis is called bent DNA, or curved DNA. Interestingly, biologically important DNA regions often contain this structure, irrespective of the origin of DNA. In the last decade, considerable progress has been made in clarifying one role of bent DNA in prokaryotic transcription and its mechanism of action. However, the role of bent DNA in eukaryotic transcription remains unclear. Our recent study raises the possibility that bent DNA is implicated in the "functional packaging" of transcriptional regulatory regions into chromatin. In this article, I review recent progress in bent DNA research in eukaryotic transcription, and summarize the history of bent DNA research and several subjects relevant to this theme. Finally, I propose a hypothesis that bent DNA structures that mimic a negative supercoil, or have a right-handed superhelical writhe, organize local chromatin infrastructure to help the very first interaction between cis-acting DNA elements and activators that trigger transcription.

Kin protein expression: laminar specificity during rat cerebral cortex development

Kin is a mammalian nuclear protein involved in DNA recombination-repair and the regulation of gene expression. The present study explored the expression of the Kin nuclear protein during postnatal development of the rat cerebral cortex, using immunocytochemistry with anti-RecA antibodies. The immunostaining of the Kin protein preferentially occurs within layers IV-V and VIb of the cortex in early postnatal developing brain, whereas in the adult rat this expression is observed unequivocally in all cortical layers. 35S-isotopic in situ hybridization for Kin-17 mRNA confirmed this Kin protein expression pattern and demonstrated its transcription in cortical neurons. This gradual age-related expression during development may have functional implications in the maturation processes of the cortex.

Overexpression of kin17 protein forms intranuclear foci in mammalian cells

We used antibodies against E coli RecA protein to identify in mouse cells a 45-kDa DNA-binding protein called kin17, which has an active zinc finger and a nuclear localisation signal. Kin17 protein produced in E coli binds preferentially to the curved DNA of a bacterial promoter in vivo and in vitro, suggesting a transcriptional regulation activity. The fact that in rodent cells kin17 protein levels increase after gamma-irradiation suggests its participation in a cellular response to ionising radiation. We raised polyclonal antibodies against the whole kin17 protein and against its derived synthetic peptides. We report the detection of kin17 protein and of truncated forms of the protein by Western blot or by immunocytochemistry after transient overexpression in cultured human cells. Our results indicate that the cross-reactivity with the anti-RecA antibodies is due to an antigenic determinant located in the core of kin17 protein, between residues 129 and 228. The kin17 protein is located in the nucleus and is concentrated in small nuclear dot-like structures throughout the nucleoplasm. The RecA homologous region seems to play an essential role in the localisation of kin17 protein since the deletion of this particular region dramatically changes the form and the distribution of the intranuclear foci. We hypothesise that these dot-like structures reflect nuclear metabolism compartmentalization.

Preferential expression of kin, a nuclear protein binding to curved DNA, in the neurons of the adult rat

The KIN17 gene product has been identified by cross immunoreactivity with anti-RecA antibodies and by DNA recombination techniques, and is probably part of the DNA recombination-repair machinery. Following Western blotting and immunocytochemistry using anti-RecA antibodies, and in situ hybridization with specific KIN17 cDNA probes, we here report the detection of high levels of KIN protein and KIN17 mRNA in the CNS of adult rats. The RecA cross-reacting protein has an apparent molecular weight of 41 kDa and is located in the nucleus of brain cells. Both the KIN17 transcript and the protein were found to be widespread, but they were present in different proportions, depending on the type of brain cells. High levels of KIN protein were seen in neurons of the motor nuclei of the brainstem, the locus coeruleus, hippocampal formation, entorhinal cortex, Purkinje cells, pyramidal cells of the cortex and mitral cells. In contrast, using a combination of KIN17 mRNA in situ hybridization and GFAP immunocytochemistry (a marker of glial cells) showed that the KIN17 messenger is preferentially transcribed in neurons, the post-mitotic and long lived brain cells. We postulate that KIN17 play a role in the illegitimate recombination of DNA sequences and/or the repair of alterations of the genome in neurons.

Quantitation of the inhibition of Hfr x F- recombination by the mutagenesis complex UmuD'C

The UmuD'C complex and RecA protein are two essential components in mutagenic repair of gaps produced by the replication of damaged DNA. In this process, the UmuD'C complex might help DNA polymerase to synthesize DNA across a lesion. Besides, a RecA polymer wrapping around single-stranded DNA could function as a directional chaperone to target the UmuD'C complex at the lesion. It was shown in our laboratory that the UmuD'C complex prevents homologous recombination and recombinational repair when expressed at elevated levels. To find out whether the UmuD'C complex inhibits recombination by interfering directly with RecA, we measured the kinetics of inhibition of Hfr x F- recombination in F- recipients in which either RecA or UmuD'C were made to vary. The cell concentrations of RecA and UmuD'C proteins were adjusted by having the recA and the umuD'C genes regulated by the arabinose P(BAD) promoter. In the absence of the UmuD'C complex, recombination was a function of RecA concentration and then reached a plateau when the RecA concentration was above 9000 monomers/cell. At a fixed RecA concentration, the yield of Hfr x F- recombinants decreased as a function of the UmuD'C cell concentration. At a given UmuD'C/RecA ratio, recombination inhibition by UmuD'C was reversed by increasing the RecA cell concentration. RecA1730, a mutant protein impaired in the chaperone activity, was insensitive to UmuD'C inhibition. We propose a model accounting for the RecA chaperone function in SOS mutagenesis and for the UmuD'C inhibitory effect on homologous recombination. We suggest that the UmuD'C complex is placed at the tip of a RecA polymer as a result of a treadmilling process. This would position the UmuD'C complex right at a lesion while the capping by UmuD'C would destabilize a RecA polymer and thereby abort the recombination process.

The sequence of a 54.7 kb fragment of yeast chromosome XV reveals the presence of two tRNAs and 24 new open reading frames

A 54,719 bp fragment from the right arm of Saccharomyces cerevisiae chromosome XV has been sequenced from the inserts of two cosmids (pEOA213 and pEOA217). The computer analysis of this sequence has revealed the presence of eight known genes (CKA2, CYC1, ALG8, TCM1, TMP1, UFE1, RTS2 and ASE1) and four open reading frames (ORFs) with strong homologies with known yeast genes (MLP1, SIS2 and HBS1 and the allantoin permease). The characteristics of the other ORFs and of the corresponding proteins do not allow postulation of a precise function. Several have features reminiscent of cytoskeleton or motor elements (keratin-like, myosin-like) and several others have characteristics of proteins which interact with DNA (extremely basic, b-Zip structure and/or acidic domains). Two tRNAs (tRNA(Lys) and tRNA(Pro)) have also been identified on this fragment. Many of these ORFs present similarities with ORFs located on chromosome XI, indicating some information reshuffling between the two chromosomal fragments.

The mouse Kin-17 gene codes for a new protein involved in DNA transactions and is akin to the bacterial RecA protein

We have sought to characterize the molecular basis of the sensitivity to ionising radiation and to identify the genes involved in the cellular response of mammalian cells to such radiation. Using the Escherichia coli model, we tested the hypothesis that functional domains of RecA protein are represented in proteins of mammalian cells. We review here the results obtained in the detection of nuclear proteins of mammalian cells that are recognized by anti-RecA antibodies. We have called them kin proteins. Kin proteins likely play a role in DNA metabolism. We summarize the cloning of the mouse Kin-17 cDNA and our work on the identification and preliminary characterisation of the biochemical properties of mouse kin17 protein, a new nuclear protein able to recognize bent DNA and suspected to be involved in illegitimate recombination. We briefly describe our latest experiments on the molecular characterisation of the mouse Kin-17 gene. Finally, we discuss the properties of kin17 protein and the possible participation of kin17 protein in DNA transactions like transcription or recombination.

Characterization of Reca Mediated homologous pairing on nitrocellulose membrane

Reactions between a single-stranded DNA (ssDNA) and a double-stranded DNA (dsDNA) provide an efficient model to study RecA promoted homologous recombination. We have devised an assay in which the ssDNA is first bound to a nitrocellulose membrane. RecA protein is loaded on this membrane (loading step) which is then incubated with a labelled homologous dsDNA (incubation step). Since this assay can be used for study of mutant RecA proteins or RecA-like activities in crude extracts from other organisms, we have characterized the reaction promoted on the membrane. Under these new conditions, the reaction keeps the main characteristics observed with classical assays performed in solution: increasing NaCl concentration destabilized the RecA-DNA complex, ATP gamma S was required for formation of stable RecA-DNA complex, initiation of the reaction exhibits the same polarity as in classical assays, a complete strand exchange with a 44 bp long duplex oligonucleotide has been recorded under our conditions. Moreover, our results indicate that the binding of RecA protein itself to the nitrocellulose membrane did not impair its ability to promote homologous pairing. Pairing reactions involving long dsDNA (6407 bp) were more efficient with hydrolysable ATP than with ATP gamma S only when the ssDNA was bound to the membrane. Furthermore, ATP hydrolysis was not required when using short dsDNA (44 bp). These results constitute experimental support for a new role for the ATPase activity of RecA protein: the energy produced could favor the initiation of RecA mediated recombination involving long stretches of DNA which have restricted freedom to rotation.

The appearance of the UmuD'C protein complex in Escherichia coli switches repair from homologous recombination to SOS mutagenesis

The process of SOS mutagenesis in Escherichia coli requires (i) the replisome enzymes, (ii) RecA protein, and (iii) the formation of the UmuD'C protein complex which appears to help the replisome to resume DNA synthesis across a lesion. We found that the UmuD'C complex is an antagonist of RecA-mediated recombination. Homologous recombination in an Hfr x F- cross decreased as a function of the UmuD'C cell concentration; this effect was challenged by increasing RecA concentration. Recombination of a u.v.-damaged F-lac with the lac gene of an F- recipient was reduced by increasing the UmuD'C concentration while lac mutagenesis increased, showing an inverse relationship between recombination and SOS mutagenesis. We explain our data with the following model. The kinetics of appearance of the UmuD'C complex after DNA damage is slow, reaching a maximum after an hour. Within that period, excision and recombinational repair have had time to occur. When the UmuD'C concentration relative to the number of residual RecA filaments, not resolved by recombinational repair, becomes high enough, UmuD'C proteins provide a processive factor for the replisome to help replication bypass and repel the standing RecA filament. Thus, at a high enough concentration, the UmuD'C complex will switch repair from recombination to SOS mutagenesis.

Induction of only one SOS operon, umuDC, is required for SOS mutagenesis in Escherichia coli

The actions of UmuDC and RecA proteins, respectively in SOS mutagenesis are studied here with the following experimental strategy. We used lexAl (Ind-) bacteria to maintain all SOS proteins at their basal concentrations and then selectively increased the concentration of either UmuDC or RecA protein. For this purpose, we isolated operator-constitutive mutations oc in the umuDC and umuD'C operons and also used the oc98-recA mutation. The oc1-umuDC mutation prevents LexA repressor from binding to the operator and improves the Pribnow box consensus sequence. As a result, 5000 UmuD and 500 UmuC molecules per cell were produced in lexAl bacteria. This concentration is sufficient to restore SOS mutagenesis. The level of RecA protein present in the repressed state promoted full UmuD cleavage. Overproduction of RecA alone did not promote SOS mutagenesis. Increasing the level of RecA in the presence of high concentrations of UmuDC proteins has no further effect on SOS mutagenesis. We conclude that, after DNA damage, umuDC is the only SOS operon that must be induced in Escherichia coli to promote SOS mutagenesis.

PsiB, and anti-SOS protein, is transiently expressed by the F sex factor during its transmission to an Escherichia coli K-12 recipient

PsiB, an anti-SOS protein, shown previously to prevent activation of RecA protein, was purified from the crude extract of PsiB overproducing cells. PsiB is probably a tetrameric protein, whose subunit has a sequence-deduced molecular mass of 15741 daltons. Using an immuno-assay with anti-PsiB antibodies, we have monitored PsiB cell concentrations produced by F and R6-5 plasmids: the latter type produces a detectable level of PsiB protein while the former does not. The discrepancy can be assigned to a Tn10 out-going promoter located upstream of psiB. When we inserted a Tn10 promoter upstream of F psiB, the F PsiB protein concentration reached the level of R6-5 PsiB. We describe here the physiological role that PsiB protein may have in the cell and how it causes an anti-SOS function. We observed that PsiB protein was transiently expressed by a wild-type F sex factor during its transmission to an Escherichia coli K-12 recipient. In an F+ x F- cross, PsiB concentration increased at least 10-fold in F- recipient bacteria after 90 minutes and declined thereafter; the psiB gene may be repressed when F plasmid replicates vegetatively. PsiB protein may be induced zygotically so as to protect F single-stranded DNA transferred upon conjugation. PsiB protein, when overproduced, may interfere with RecA protein at chromosomal single-stranded DNA sites generated by discontinuous DNA replication, thus causing an SOS inhibitory phenotype.

Identification and expression of the cDNA of KIN17, a zinc-finger gene located on mouse chromosome 2, encoding a new DNA-binding protein

We report the cloning of KIN17 cDNA, 1414 bp long with an ORF of 391 residues showing a zinc finger and nuclear localization signals. By recloning the cDNA into an appropriate vector, we produced kin17 protein in E. coli, purified it partially and shown that kin17 protein binds to double-stranded DNA. The KIN17 gene was localized by cytogenetic mapping in mouse chromosome 2, band A. Genomic sequences homologous to KIN17 cDNA were detected also in rat and human DNAs. KIN17 mRNA is highly expressed in rodent transformed AtT-20 neuroendocrine cells whereas it can be detected only in the total RNA of mouse embryos and various normal adult tissues by reverse transcription and PCR amplification. The mouse nuclear kin17 protein was identified by a local small structural similarity with E.coli recA protein. Kin17 and recA have only 39 amino acid residues in a region that might be involved in DNA-binding.