Recent Advances in Studies of Skin Color and Skin Cancer.

The relationship between skin color and skin cancer is well established: the less melanin in one's skin the greater the risk for developing skin cancer. This review is in two parts. First, we summarize the current understanding of the cutaneous pigmentary system and trace melanin from its synthesis in the pigment cell melanosomes through its transfer to keratinocytes. We also present new methods for reducing melanin content in hyper-pigmented areas of skin such as solar lentigenes, melasma, and post-inflammatory hyperpigmentation. Second, we present evidence that at least one mechanism for the development of metastatic melanoma and other solid tumors is fusion and hybridization of leucocytes such as macrophages with primary tumor cells. In this scenario, hybrid cells express both the chemotactic motility of the leucocyte and the de-regulated cell division of the tumor cell, causing the cells to migrate a deadly journey to lymph nodes, distant organs, and tissues.

Leukocyte⁻Cancer Cell Fusion-Genesis of a Deadly Journey.

According to estimates from the International Agency for Research on Cancer, by the year 2030 there will be 22 million new cancer cases and 13 million deaths per year. The main cause of cancer mortality is not the primary tumor itself but metastasis to distant organs and tissues, yet the mechanisms of this process remain poorly understood. Leukocyte⁻cancer cell fusion and hybrid formation as an initiator of metastasis was proposed more than a century ago by the German pathologist Prof. Otto Aichel. This proposal has since been confirmed in more than 50 animal models and more recently in one patient with renal cell carcinoma and two patients with malignant melanoma. Leukocyte⁻tumor cell fusion provides a unifying explanation for metastasis. While primary tumors arise in a wide variety of tissues representing not a single disease but many different diseases, metastatic cancer may be only one disease arising from a common, nonmutational event: Fusion of primary tumor cells with leukocytes. From the findings to date, it would appear that such hybrid formation is a major pathway for metastasis. Studies on the mechanisms involved could uncover new targets for therapeutic intervention.

Sperm cell purification from mock forensic swabs using SOMAmer™ affinity reagents.

We have demonstrated a proof of concept with affinity-based purification of sperm cells from mock forensic samples using SOMAmer™ reagents, DNA-based affinity reagents developed by SomaLogic, Inc. SOMAmer reagents were selected in vitro using whole-cell SELEX to bind specifically with intact, detergent-treated sperm cells. Successful separation of sperm from epithelial cells and their debris was demonstrated using buccal swabs with added semen. Primarily male DNA profiles were generated from sperm cells eluted from the types of cotton swabs typically used for rape kit evidence collection. The quality of sperm DNA isolated from samples purified using SOMAmers is comparable to existing commercially available differential extraction-based methods at higher sperm concentrations. This purification method is simple, offers relatively rapid (<2hr) sperm purification, and can potentially be automated using robotic workstations. This work serves as proof of concept that demonstrates the first use of SOMAmer reagents as affinity ligands to bind sperm cells. With further development, this technique can potentially be used for high-throughput sexual assault forensic casework.

A Melanoma Lymph Node Metastasis with a Donor-Patient Hybrid Genome following Bone Marrow Transplantation: A Second Case of Leucocyte-Tumor Cell Hybridization in Cancer Metastasis.

BACKGROUND: Metastatic disease is the principal cause of mortality in cancer, yet the underlying mechanisms are not fully understood. Macrophage-cancer cell fusion as a cause of metastasis was proposed more than a century ago by German pathologist Prof. Otto Aichel. Since then this theory has been confirmed in numerous animal studies and recently in a patient with metastatic melanoma. METHODS: Here we analyzed tumor DNA from a 51-year-old man who, 8 years following an allogeneic BMT from his brother for treatment of chronic myelogenous leukemia (CML), developed a nodular malignant melanoma on the upper back with spread to an axillary sentinal lymph node. We used laser microdissection to isolate FFPE tumor cells free of leucocytes. They were genotyped using forensic short tandem repeat (STR) length-polymorphisms to distinguish donor and patient genomes. Tumor and pre-transplant blood lymphocyte DNAs were analyzed for donor and patient alleles at 15 autosomal STR loci and the sex chromosomes. RESULTS: DNA analysis of the primary melanoma and the nodal metastasis exhibit alleles at each STR locus that are consistent with both the patient and donor. The doses vary between these samples indicative of the relative amounts of genomic DNA derived from the patient and donor. CONCLUSION: The evidence supports fusion and hybridization between donor and patient cells as the initiator of metastasis in this patient. That this phenomenon has now been seen in a second case suggests that fusion is likely to play a significant role for melanoma and other solid tumor metastasis, perhaps leading to new avenues of treatment for this most problematic disease.

A Melanoma Brain Metastasis with a Donor-Patient Hybrid Genome following Bone Marrow Transplantation: First Evidence for Fusion in Human Cancer.

BACKGROUND: Tumor cell fusion with motile bone marrow-derived cells (BMDCs) has long been posited as a mechanism for cancer metastasis. While there is much support for this from cell culture and animal studies, it has yet to be confirmed in human cancer, as tumor and marrow-derived cells from the same patient cannot be easily distinguished genetically. METHODS: We carried out genotyping of a metastatic melanoma to the brain that arose following allogeneic bone-marrow transplantation (BMT), using forensic short tandem repeat (STR) length-polymorphisms to distinguish donor and patient genomes. Tumor cells were isolated free of leucocytes by laser microdissection, and tumor and pre-transplant blood lymphocyte DNAs were analyzed for donor and patient alleles at 14 autosomal STR loci and the sex chromosomes. RESULTS: All alleles in the donor and patient pre-BMT lymphocytes were found in tumor cells. The alleles showed disproportionate relative abundances in similar patterns throughout the tumor, indicating the tumor was initiated by a clonal fusion event. CONCLUSIONS: Our results strongly support fusion between a BMDC and a tumor cell playing a role in the origin of this metastasis. Depending on the frequency of such events, the findings could have important implications for understanding the generation of metastases, including the origins of tumor initiating cells and the cancer epigenome.

CTLA4 and generalized vitiligo: two genetic association studies and a meta-analysis of published data.

Several lines of evidence have implicated the gene encoding cytotoxic T lymphocyte antigen 4 (CTLA4) in susceptibility to various autoimmune diseases. However, published studies of genetic association between CTLA4 polymorphisms and vitiligo have yielded conflicting results. Here, we describe two new genetic association studies of CTLA4 single-nucleotide polymorphisms (SNPs) and generalized vitiligo in two independent Romanian Caucasian (CEU) case-control cohorts. The first study, of SNPs rs1863800, rs231806, rs231775, rs3087243, rs11571302, rs11571297, and rs10932037, showed no allelic, genotypic, or haplotypic association with generalized vitiligo. The second study, of SNP rs231775, likewise showed no significant association. To enhance statistical power over that of any individual study, we carried out a meta-analysis that incorporated these two new studies and all other published genetic association studies of CTLA4 SNPs and vitiligo in CEU populations. While there was no association with vitiligo overall, the meta-analysis showed significant association of SNP rs231775 in that subgroup of vitiligo patients who also had other concomitant autoimmune diseases. Similarly, there was near-significant association in this same patient subgroup with several other CTLA4 SNPs that are in linkage disequilibrium with rs231775. Our results indicate that the association of CTLA4 with vitiligo is weak, and indeed may be secondary, driven by primary genetic association of CTLA4 with other autoimmune diseases that are epidemiologically associated with vitiligo.

The PTPN22-1858C>T (R620W) functional polymorphism is associated with generalized vitiligo in the Romanian population.

Generalized vitiligo is an autoimmune disorder of the skin in which autoimmune-mediated destruction of melanocytes leads to depigmented patches of skin and overlying hair. The 1858C>T (R620W) functional polymorphism of the PTPN22 gene, which encodes lymphoid protein tyrosine phosphatase (Lyp), has been associated with susceptibility to a number of autoimmune disorders, including generalized vitiligo. The aim of this study was to test genetic association of the PTPN22 1858C>T variant and generalized vitiligo in a Romanian case-control cohort. We observed significant association of generalized vitiligo with the 1858T risk allele of PTPN22 [P = 0.0138; OR = 2.92 (1.21-7.03)], with significantly different distribution of PTPN22 1858C>T genotypes in cases versus controls [P = 0.036; OR = 2.69 (1.07-6.80)]. Our results provide evidence that the PTPN22 1858T allele contributes to risk of generalized vitiligo in European Caucasian populations, and underscores the importance of a genetically mediated autoimmune mechanism in the pathogenesis of vitiligo.

PTPN22 is genetically associated with risk of generalized vitiligo, but CTLA4 is not.

Generalized vitiligo is an acquired, multifactorial, polygenic disease in which depigmented spots of skin, overlying hair, and mucus membranes result from autoimmune-mediated loss of melanocytes from affected areas. We examined single-nucleotide polymorphisms (SNPs) in the PTPN22 and CTLA4 genes in 126 Caucasian families with multiple cases of generalized vitiligo and associated autoimmune diseases, using a family-based association study design. The PTPN22 1858T allele of SNP rs2476601 is significantly associated both with generalized vitiligo and with an expanded autoimmunity phenotype. Individuals carrying the PTPN22 1858T allele had an allelic odds ratio (OR) of 2.16 for generalized vitiligo and a genotypic OR of 2.35 as C/T heterozygotes. Similarly, individuals carrying the PTPN22 1858T allele had an allelic OR of 2.05 for the expanded autoimmunity phenotype, and a genotypic OR of 2.19 for C/T heterozygotes. Examination of five SNPs in the CTLA4 gene (rs1863800, rs231775, rs3087243, rs11571302, rs11571297, rs10932037) in the same 126 families yielded no evidence of allelic or genotypic association with either generalized vitiligo or the expanded autoimmune phenotype. These results implicate PTPN22 in mediating susceptibility to generalized vitiligo and associated autoimmune diseases, but do not support a role for CTLA4.

Separating human DNA mixtures using denaturing high-performance liquid chromatography.

DNA mixtures represent challenging samples that are rarely amenable to direct DNA sequence analysis and many of the strategies available to separate mixtures are both labor and time intensive. Denaturing high-performance liquid chromatography is an accurate and rapid approach for the detection and scoring of mutations. It can also be used to separate DNA mixtures. The technique relies on the chromatographic separation of crosshybridization products to isolate the individual components of a mixture. By eliminating secondary amplification and excessive manipulation prior to sequencing, denaturing high-performance liquid chromatography can streamline the analysis of conditions ranging from somatic mosaicism, microchimerism and mitochondrial heteroplasmy to evidentiary material containing mixtures of DNA encountered in forensic investigations.

Clinical applications of denaturing high-performance liquid chromatography-based genotyping.

AIM: To develop and evaluate heteroduplex forming templates (HFTs) as a common set of molecular standards for genotyping by denaturing high-performance liquid chromatography (DHPLC) using hypervariable regions of human mitochondrial DNA (mtDNA) as a model system. METHODS: Hypervariable regions 1 and 2 from the mtDNA D-loop of 22 maternally related and unrelated human volunteers were amplified by polymerase chain reaction (PCR) and individually mixed with each of three HFTs. Following denaturation and reannealing of the mixture, the resulting hetero- and homoduplicies were separated by DHPLC using temperature-modulated heteroduplex analysis. RESULTS: Each of three HFTs, when cross-hybridized with a target mtDNA amplicon, induced the formation of an assemblage hetero- and homoduplex peaks, which were uniquely characteristic of a given mtDNA sequence variant. The mtDNA DHPLC profiles obtained in the current study were identical between maternal relatives and different between unrelated individuals--consistent with uniparental maternal inheritance of mtDNA in humans. CONCLUSION: DHPLC in combination with a common set of HFTs targeted to a locus of interest can be used as a reliable means of genotyping. DHPLC profiles can be readily stored as a bit-coded string of hetero- and homoduplex peak retention times to form a searchable database. This approach to DHPLC genotyping will have immediate utility in extended pedigree analyses, where it will allow rapid sorting and/or confirmation of maternal lineages. Additional applications of DHPLC profiling include the discovery and scoring of clinically relevant nuclear and mitochondrial loci.

Forensic utility of mitochondrial DNA analysis based on denaturing high-performance liquid chromatography.

AIM: To determine the forensic utility for pairwise DNA comparisons and DNA mixture resolution with denaturing high-performance liquid chromatography (DHPLC) of human mitochondrial DNA (mtDNA). METHODS: MtDNA hypervariable regions (HV) 1 and 2 from the mtDNA D-loop were amplified by the polymerase chain reaction and mixed between known and unknown sample sources. The DNA mixtures were denatured and reannealed, and the resultant homo- and heteroduplices were evaluated by temperature-modulated heteroduplex analysis by the DHPLC method. RESULTS: All 144 pairwise comparisons of HV1 and HV2 mtDNA fragments were successfully resolved by the DHPLC method. Forensic proficiency test standards were successfully resolved and DHPLC match/non-match results agreed with sequencing results provided by the test providers. The DHPLC method successfully identified one questioned sample that was prepared by the test provider as a body fluid mixture. MtDNA amplicon mixtures could be separated into their constitutive components by DHPLC and fraction collection approaches. CONCLUSIONS: DHPLC methods provide the forensic scientist with a powerful tool to rapidly screen mtDNA and may result in standardized methods to resolve mtDNA mixtures. These advances will allow mtDNA analysis in cases not previously examined by current sequencing-based approaches and could allow more forensic case samples to be entered into the proposed mtDNA Combined DNA Index System (CODIS trade mark ) databank as a result of mtDNA mixture resolution.

A genomewide screen for generalized vitiligo: confirmation of AIS1 on chromosome 1p31 and evidence for additional susceptibility loci.

Generalized vitiligo is a common autoimmune disorder characterized by the development of white patches of skin and overlying hair due to loss of pigment-forming melanocytes from the involved areas. Family clustering of cases is not uncommon, in a pattern suggestive of multifactorial, polygenic inheritance, and there is strong association between vitiligo and other autoimmune diseases. To map genetic loci that confer susceptibility to generalized vitiligo and perhaps other autoimmune diseases, we performed a genomewide linkage scan in 71 white multiplex families with vitiligo from North America and the United Kingdom. Linkage was assessed by multipoint nonparametric linkage analyses. One linkage signal, AIS1, located at 1p31, met genomewide criteria for highly significant linkage (nonparametric LOD 5.56; P=.000000282), establishing its importance as a major vitiligo susceptibility locus. An additional seven signals, on chromosomes 1, 7, 8, 11, 19, and 22, met genomewide criteria for "suggestive linkage," and will thus be of particular importance for follow-up studies.