Langerhans cell: exciting developments in health and disease.

Langerhans cells (LCs) have been the subject of much research since their discovery in 1868. LCs belong to the subset of leucocytes called dendritic cells. They are present in the epidermis and the pilosebaceous apparatus and monitor the cutaneous environment for changes in homeostasis. During embryogenesis, a wave of yolk sac macrophages seed the fetal skin. Then, fetal liver monocytes largely replace the yolk sac macrophages and comprise the majority of adult LCs. In the presence of skin irritation, LCs process antigen and travel to regional lymph nodes to present antigen to reactive T lymphocytes. Changes in LCs' surface markers during the journey occur under the influence of cytokines. The difference in expression of surface markers and the ability to resist radiation have allowed researchers to differentiate LCs from the murine Langerin-positive dermal dendritic cells. Exciting discoveries have been made recently regarding their role in inflammatory skin diseases, cancer and HIV. New research has shown that antibodies blocking CD1a appear to mitigate inflammation in contact hypersensitivity reactions and psoriasis. While it has been established that LCs have the potential to induce effector cells of the adaptive immune system to counter oncogenesis, recent studies have demonstrated that LCs coordinate with natural killer cells to impair development of squamous cell carcinoma caused by chemical carcinogens. However, LCs may also physiologically suppress T cells and permit keratinocyte transformation and tumorigenesis. Although long known to play a primary role in the progression of HIV infection, it is now understood that LCs also possess the ability to restrict the progression of the disease. There is a pressing need to discover more about how these cells affect various aspects of health and disease; new information gathered thus far seems promising and exciting.

Xeroderma pigmentosum complementation group A protein acts as a processivity factor.

We have previously shown that endonucleases present in a protein complex, which has specificity for cyclobutane pyrimidine dimers, locate sites of damage in DNA by a processive mechanism of action in normal human lymphoblastoid cells. In contrast, the endonucleases present in this complex from xeroderma pigmentosum complementation group A (XPA) cells locate damage sites by a distributive or significantly less processive mechanism. Since the XPA protein has been shown to be responsible for the DNA repair defect in XPA cells, this protein was examined for involvement in the mechanism of target site location of these endonucleases. A recombinant XPA protein, produced by expression of the normal XPA cDNA in E. coli, was isolated and purified. The results show that the recombinant XPA protein was able to correct the defect in ability of the XPA endonucleases to act by a processive mechanism of action on UVC irradiated DNA. These studies indicate that the XPA protein, in addition to a role in damage recognition or damage verification, may function as a processivity factor.

Fanconi anemia, complementation group A, cells are defective in ability to produce incisions at sites of psoralen interstrand cross-links.

The hypersensitivity of Fanconi anemia, complementation group A, (FA-A) cells to agents which produce DNA interstrand cross-links correlates with a defect in their ability to repair this type of damage. In order to more clearly elucidate this repair defect, chromatin-associated protein extracts from FA-A cells were examined for ability to endonucleolytically produce incisions in DNA at sites of interstrand cross-links. A defined 140 bp DNA substrate was constructed with a single site-specific monoadduct or interstrand cross-link produced by 4,5',8-trimethylpsoralen (TMP) plus long wavelength (UVA) light. Our results show that FA-A cells are defective in ability to produce dual incisions in DNA at sites of interstrand cross-links. Specifically, there is defective incision on the 3'- and 5'-sides of both the furan and pyrone sides of the cross-link. This defect is corrected in FA-A cells transduced with a retroviral vector expressing FANCA cDNA. At the site of a TMP monoadduct, FA-A cells can introduce incisions on both the 3'- and 5'-sides of the furan side monoadduct, but are defective in ability to produce these incisions on the pyrone side monoadduct. These studies also indicate that XPF is involved in production of the 5' incision by the normal extracts on these substrates. These results correlate with our previous work, which showed that FA-A cells are mainly defective in ability to repair psoralen interstrand cross-links with a lesser defect in ability to repair psoralen monoadducts. This defect in endonucleolytic incision at sites of TMP interstrand cross-links could be related to reduced levels of non-erythroid alpha spectrin (alphaSpIISigma*) in the extracts from FA-A cells. alphaSpIISigma* could act as a scaffold to align proteins involved in cross-link repair and enhance their interactions; a deficiency in alphaSpIISigma* could thus lead to reduced efficiency of repair and the decreased levels of incisions we observe at sites of interstrand cross-links in FA-A cells.

Human alpha spectrin II and the Fanconi anemia proteins FANCA and FANCC interact to form a nuclear complex.

Fanconi anemia (FA) is a genetic disorder characterized by bone marrow failure, congenital abnormalities, cancer susceptibility, and a marked cellular hypersensitivity to DNA interstrand cross-linking agents, which correlates with a defect in ability to repair this type of damage. We have previously identified an approximately 230-kDa protein present in a nuclear protein complex in normal human lymphoblastoid cells that is involved in repair of DNA interstrand cross-links and shows reduced levels in FA-A cell nuclei. The FANCA gene appears to play a role in the stability or expression of this protein. We now show that p230 is a well known structural protein, human alpha spectrin II (alphaSpIISigma*), and that levels of alphaSpIISigma* are not only significantly reduced in FA-A cells but also in FA-B, FA-C and FA-D cells (i.e. in all FA cell lines tested), suggesting a role for these FA proteins in the stability or expression of alphaSpIISigma*. These studies also show that alphaSpIISigma* forms a complex in the nucleus with the FANCA and FANCC proteins. alphaSpIISigma* may thus act as a scaffold to align or enhance interactions between FA proteins and proteins involved in DNA repair. These results suggest that FA represents a disorder in which there is a deficiency in alphaSpIISigma*.

A deficiency in a 230 kDa DNA repair protein in fanconi anemia complementation group A cells is corrected by the FANCA cDNA.

Cells from individuals with the cancer-prone, inherited disorder Fanconi anemia (FA) are hypersensitive to DNA interstrand cross-linking agents and this hypersensitivity correlates with a defect in ability to repair this type of damage to their DNA. We have isolated a DNA endonuclease complex from the nuclei of normal human cells which is involved in repair of DNA interstrand cross-links and have shown that in FA complementation group A (FA-A) cells there is a defect in ability of this complex to incise DNA containing interstrand cross-links. In order to identify the specific protein(s) in this complex which is defective in FA-A cells, monoclonal antibodies (mAbs) were developed against proteins in the normal complex. One of these mAbs, which is against a protein with a molecular weight of approximately 230 kDa, completely inhibited the ability of the normal complex to incise cross-linked DNA. Western blot analysis has shown that there is a deficiency in this protein in FA-A cells. Electophoretic analysis has also indicated that there are reduced levels of this protein in FA-A compared with normal cells. Studies carried out utilizing FA-A cells which have been stably transduced with a retroviral vector expressing the FANCA cDNA have shown that the DNA repair defect in these cells has been corrected; levels of unscheduled DNA synthesis are at least as great as those of normal human cells. In addition, in the transduced cells the deficiency in the 230 kDa protein has been corrected, as determined by both western blot and electrophoretic analysis. These results indicate that the FANCA gene plays a role in the expression or stability of the 230 kDa protein.

A processive versus a distributive mechanism of action correlates with differences in ability of normal and xeroderma pigmentosum group A endonucleases to incise damaged nucleosomal DNA.

A DNA endonuclease, isolated from the nuclei of normal human and xeroderma pigmentosum complementation group A (XPA) cells, which recognizes predominately pyrimidine dimers, was examined for the mechanism by which it locates sites of damage on UVC-irradiated DNA. In reaction mixtures with low ionic strengths (i.e. lacking KCl), the normal and XPA endonuclease locate sites of UV damage on both naked and reconstituted nucleosomal DNA by different mechanisms. On both of these substrates, the normal endonuclease acts by a processive mechanism, meaning that it binds non-specifically to DNA and scans the DNA for sites of damage, whereas the XPA endonuclease acts by a distributive one, meaning that it randomly locates sites of damage on DNA. However, while both the normal and XPA endonucleases can incise UVC irradiated naked DNA, they differ in ability to incise damaged nucleosomal DNA. The normal endonuclease showed increased activity on UVC treated nucleosomal DNA compared with naked DNA, whereas the XPA endonuclease showed decreased activity on the damaged nucleosomal substrate. Since a processive mechanism of action is sensitive to the ionic strength of the micro-environment, the KCl concentration of the reaction was increased. At 70 mM KCI, the normal endonuclease switched to a distributive mechanism of action and its ability to incise damaged nucleosomal DNA also decreased. These studies show that there is a correlation between the ability of these endonucleases to act by a processive mechanism and their ability to incise damaged nucleosomal DNA; the normal endonuclease, which acts processively, can incise damaged nucleosomal DNA, whereas the XPA endonuclease, which acts distributively, is defective in ability to incise this substrate.

Xeroderma pigmentosum.

Xeroderma pigmentosum is a rare, recessively transmitted disease associated with increased sensitivity to ultraviolet radiation in wavelengths found in sunlight, development of cancers in sun-exposed areas of the body in much larger numbers and much earlier in life than in normal individuals, and in some patients, neurologic deficiencies unrelated to sun exposure. Extensive cellular, biochemical, and molecular genetic studies in numerous laboratories have revealed that cells derived from patients with this disease have defective repair of ultraviolet-light-induced damage in cellular DNA, and that extensive genetic heterogeneity and numerous distinct genes are involved in the genetics of this disease and the etiopathogenesis of its associated changes. A number of these genes and gene products are now being, or have been, cloned, and their gene products characterized.

Isolation of a DNA endonuclease complex in XPD cells which is defective in ability to incise nucleosomal DNA containing pyrimidine dimers.

A DNA endonuclease complex which recognizes predominantly pyrimidine dimers in UVC irradiated DNA has been isolated from the chromatin of normal human and xeroderma pigmentosum, complementation group D (XPD) lymphoblastoid cells. The activity of the normal complex on UVC irradiated DNA was increased approximately 2.5 and 1.5 fold over activity on damaged naked DNA, when core (histones H2A, H2B, H3, H4) and total (core+histone H1) nucleosomal DNA, respectively, was used. In contrast, the XPD complex showed no increase in activity on UVC irradiated total and only a 1.4 fold increase on UVC irradiated core nucleosomal DNA, indicating that the XPD complex is defective in its ability to incise UVC irradiated nucleosomal DNA. The normal complex was able to correct this defect in the XPD complex at the nucleosomal level.

Xeroderma pigmentosum endonuclease complexes show reduced activity on and affinity for psoralen cross-linked nucleosomal DNA.

Two DNA endonuclease complexes have been isolated from the chromatin of normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells which are active on DNA damaged with psoralen plus long wavelength ultraviolet radiation (UVA). In both normal and XPA cells, one endonuclease complex, pI 4.6, recognizes the psoralen cross-link and the other endonuclease complex, pI 7.6, recognizes the psoralen monoadduct. The levels of activity of these complexes from both normal and XPA cells are similar on damaged naked DNA. Kinetic analysis of assays using graduated concentrations of substrate revealed that selective activity of these endonuclease complexes on 8-MOP plus UVA treated DNA correlates with a reduction in Km of these complexes, indicating an increased affinity for, or rate of association with, damaged naked DNA. When the damaged substrates were reconstituted into core nucleosomes (without histone H1), both normal endonuclease complexes showed a 2.5-fold enhancement of activity, which correlated kinetically with a further increase in affinity, or rate of association (decreased Km), for this damaged nucleosomal substrate. This increase in activity and in affinity was reduced but not eliminated when histone H1 was present. By contrast, neither XPA endonuclease complex showed this enhanced activity on, or affinity for, damaged core nucleosomal DNA, and actually showed decreased activity, and affinity, when histone H1 was present. Introduction, via electroporation, of either of the normal complexes into 8-MOP plus UVA treated XPA cells in culture corrected their DNA-repair defect, further confirming the role of these complexes in the repair process.

Co-recessive inheritance: a model for DNA repair and other surveillance genes in higher eukaryotes.

The co-recessive inheritance hypothesis proposes that certain recessively inherited diseases require homozygosity and/or hemizygosity for defective alleles at more than one locus simultaneously for the trait to be expressed. Although this hypothesis was originally proposed in the context of defective alleles for genes coding for DNA-repair functions, it need not be limited to this context, and genetic selection pressure may favor this model for genes involved in surveillance of any type. The co-recessive inheritance hypothesis also predicts extremely high carrier frequencies, likely affecting much of the general population, for defective alleles associated with these rare recessive diseases. The model predicts much lower rates of consanguinity between the parents of affected individuals than autosomal recessive inheritance, allowing it to be tested epidemiologically, and recent data suggest that the hypothesis may be valid for some cases of ataxia telangiectasia and xeroderma pigmentosum. The model provides possible explanations for a number of otherwise puzzling findings in several diseases associated with defective DNA repair.

Correction of the ultraviolet light induced DNA-repair defect in xeroderma pigmentosum cells by electroporation of a normal human endonuclease.

Cells from patients with xeroderma pigmentosum, complementation group A (XPA), are known to be defective in repair of pyrimidine dimers and other forms of damage produced by 254-nm ultraviolet (UVC) radiation. We have isolated a DNA endonuclease, pI 7.6, from the chromatin of normal human lymphoblastoid cells which recognizes damage produced by UVC light, and have introduced this endonuclease into UVC-irradiated XPA cells in culture to determine whether it can restore their markedly deficient DNA repair-related unscheduled DNA synthesis (UDS). Introduction of the normal endonuclease, which recognizes predominantly pyrimidine dimers, but not the corresponding XPA endonuclease into UVC-irradiated XPA cells restored their levels of UDS to approximately 80% of normal values. Electroporation of both the normal and the XPA endonuclease into normal human cells increases UDS in normal cells to higher than normal values. These results indicate that the normal endonuclease can restore UDS in UVC-irradiated XPA cells. They also indicate that XPA cells have an endonuclease capable of increasing the efficiency of repair of UVC damage in normal cells.

Electroporation of normal human DNA endonucleases into xeroderma pigmentosum cells corrects their DNA repair defect.

Cells from patients with the cancer-prone inherited disease, xeroderma pigmentosum (XP) are known to be defective in the endonuclease-mediated incision step in excision repair of a number of different types of DNA adducts, but the molecular events responsible have not been delineated. We have previously reported isolation of two DNA endonucleases, pI 4.6 and 7.6, from normal human chromatin which recognize adducts produced by psoralen plus long wavelength ultraviolet radiation (UVA). These endonucleases are both present in XP complementation group A (XPA) cells even though these cells are hypersensitive to this type of damage. We now report that introduction by electroporation of either normal endonuclease into XPA cells restored their markedly deficient DNA repair-related unscheduled DNA synthesis (UDS) to higher than normal levels following exposure to psoralen plus UVA. Introduction of XPA endonucleases into similarly treated XPA cells had little or no restorative effect on UDS. However, both normal and XPA endonucleases increased UDS in normal cells to higher than normal levels. These results indicate that XPA cells have endonucleases which can repair these adducts but which cannot function in intact cells unless a factor(s), which they lack is provided by normal cells.

Chromatin-associated DNA endonucleases from xeroderma pigmentosum cells are defective in interaction with damaged nucleosomal DNA.

The influence of nucleosome structure on the activity of 2 chromatin-associated DNA endonucleases, pIs 4.6 and 7.6, from normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells was examined on DNA containing either psoralen monoadducts or cross-links. As substrate a reconstituted nucleosomal system was utilized consisting of a plasmid DNA and either core (H2A, H2B, H3, H4), or total (core plus H1) histones from normal or XPA cells. Both non-nucleosomal and nucleosomal DNA were treated with 8-methoxypsoralen (8-MOP) plus long-wavelength ultraviolet radiation (UVA), which produces monoadducts and DNA interstrand cross-links, and angelicin plus UVA, which produces monoadducts. Both normal endonucleases were over 2-fold more active on both types of psoralen-plus-UVA-damaged core nucleosomal DNA than on damaged non-nucleosomal DNA. Addition of histone H1 to the system reduced but did not abolish this increase. By contrast, neither XPA endonuclease showed any increase on psoralen-treated nucleosomal DNA, with or without histone H1. Mixing the normal with the XPA endonucleases led to complementation of the XPA defect. These results indicate that interaction of these endonucleases with chromatin is of critical importance and that it is at this level that a defect exists in XPA endonucleases.

Deficient DNA binding of an apurinic/apyrimidinic DNA endonuclease activity from xeroderma pigmentosum cells.

A chromatin-associated apurinic/apyrimidinic (AP) DNA endonuclease activity, pI 9.8, from both normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells was examined for its ability to bind AP DNA using a filter binding assay. The endonuclease activity from normal cells produced significantly greater binding to AP DNA than to untreated DNA, but this increase in binding was not observed when the XPA endonuclease was incubated with AP DNA versus untreated DNA. These results indicate that the XPA AP endonuclease activity is deficient in its ability to bind to AP DNA.

Two DNA endonuclease activities from normal human and xeroderma pigmentosum chromatin active on psoralen plus ultraviolet light treated DNA.

DNA endonuclease activities from the chromatin of normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells were examined on DNA treated with 8-methoxypsoralen (8-MOP) or 4,5',8-trimethylpsoralen (TMP) plus long wavelength ultraviolet (UVA) light, which produce monoadducts and DNA interstrand cross-links, and angelicin plus UVA light, which produces mainly monoadducts. 9 chromatin-associated DNA endonuclease activities were isolated from normal and XPA cells and assayed for activity on PM2 bacteriophage DNA that had been treated with 8-MOP or TMP in the dark and then exposed to UVA light. Unbound psoralen was removed by dialysis and a second dose of UVA light was given. Cross-linking of DNA molecules was confirmed by alkaline gel electrophoresis. In both normal and XPA cells, two DNA endonuclease activities were found which were active on 8-MOP and TMP plus UVA light treated DNA. One of these endonuclease activities, pI 4.6, is also active on intercalated DNA and a second one, pI 7.6, is also active on UVC (254 nm) light irradiated DNA. The major activity against angelicin plus UVA light treated DNA in both normal and XPA cells was found in the fraction, pI 7.6. The levels of activity of both of these fractions on all 3 psoralen-damaged DNAs were similar between normal and XPA cells. These results indicate that in both normal and XPA cells there are at least two different DNA endonucleases which act on both 8-MOP and TMP plus UVA light treated DNA.

Positioning of nucleosomes reconstituted with xeroderma pigmentosum and normal histones.

Positioning of nucleosomes was examined in a reconstituted system using a plasmid DNA and histones from normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells. The present studies indicate that the arrangement of nucleosomes, composed of normal human histones, in a region near the SV40 origin of replication on the plasmid DNA, is nonrandom. The alignment of nucleosomes in this region was not affected by the presence of histone H1. No difference in nucleosome positioning was observed when the nucleosomes were composed of histones from XPA cells.

Comparison of histones in normal and xeroderma pigmentosum lymphoblastoid cells.

Histones from normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells were compared both quantitatively, qualitatively and for binding affinity for DNA. Electrophoretic examination of the histones showed that all five major histone species were present in both cell groups and that there were no quantitative differences between normal and XPA histones. Binding affinity to [3H] mammalian DNA of the histones was determined. No significant differences were observed in binding of either normal or XPA histones to DNA.

Enhancement of two apurinic/apyrimidinic endonuclease activities from normal but not xeroderma pigmentosum lymphoblastoid cells by nucleosome structure.

The influence of nucleosomes on the activity of two chromatin-associated apurinic/apyrimidinic (AP) DNA endonuclease activities, pIs 9.2 and 9.8, from normal and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells was examined. These AP endonuclease activities were studied on non-nucleosomal and nucleosomal plasmid pWT830/pBR322 DNA which had been reconstituted with core (H2A, H2B, H3, H4) or total (core plus H1) histones from normal or XPA cells. Both nucleosomal and non-nucleosomal DNA was rendered partially AP by alkylation with 12.5 mM methyl methanesulfonate, followed by heating it at 70 degrees C, to produce approximately three AP sites per DNA molecule. The activities of both normal lymphoblastoid AP endonuclease activities on nucleosomal AP DNA, reconstituted with core histones, was approximately 2.5 times greater than that on non-nucleosomal AP DNA. When histone H1 was added to the system, this increase was reduced. XPA AP endonuclease activities, on the other hand, did not show any increase in activity on nucleosomal AP DNA reconstituted with core histones. These differences between normal and XPA endonuclease activities on AP nucleosomal DNA were the same regardless of whether histones from normal or XPA cells were used in the reconstituted system.