Ionic strength-controlled hybridization and stability of hybrids of KRAS DNA single-nucleotides: A surface plasmon resonance study.

The discrimination of a fully matched, unlabeled KRAS wild-type (WT) (C-G) target sample with respect to three of the most frequent KRAS codon mutations (G12 S (C-A), G12 R (C-C), G12C (C-T)) was investigated using an optimized detection strategy involving surface plasmon resonance (SPR), based on optimized probe-surface density and ionic strength control. The changes observed in the SPR signal were always larger for WT compared with the single-mismatch target DNA oligonucleotides, and were aligned with the theoretical energy differences between the base pair C-G, C-T, C-A, C-C. Hybridization rates of ∼106M-1s-1 were detected without the introduction of high temperature and labels, usually needed in conventional hybridization methods. One hundred percent mutation discrimination of the matched KRAS wild-type (C-G) sequence with respect to three mismatched G12C (C-T), G12 S (C-A), G12 R (C-C) target sequences was achieved.

Gene expression by single Reed-Sternberg cells: pathways of apoptosis and activation.

Although Hodgkin's disease is highly responsive to treatments that cause apoptosis, it remains resistant to the physiological mechanisms intended to cause cell death. Presumably, the Reed-Sternberg cell defies endogenous apoptosis, persists, accumulates, and manifests the malignant disorder seen clinically. The Reed-Sternberg cell expresses several members of the tumor necrosis factor receptor superfamily. This family of receptors is involved in both activation and proliferation of cells, as well as either protection from or initiation of apoptosis in cells expressing these surface proteins. Signals from these receptors affect transcription. We reasoned that the activation state and resistance to apoptosis of Reed-Sternberg cells might be attributable to dysregulation of genes controling these processes. To determine gene expression by Reed-Sternberg cells, we developed a method of micromanipulation, global reverse transcription, and the reverse transcription-polymerase chain reaction and applied it to 51 single Reed-Sternberg cells and their variants from six cases of Hodgkin's disease. This report analyzes the gene expression of bcl-xs, bcl-xl, bax-alpha, bax-beta, fadd, fas, fas ligand (fas L), ice, TNF-alpha, TNF-beta, TNFR1, TNFR2, TRAF1, TRAF2, TRAF3, cIAP2, and tradd at the level of mRNA in the single Reed-Sternberg cells and their variants. The findings here suggest a molecular mechanism for the activated state and in vivo survival occurring in untreated Reed-Sternberg cells of Hodgkin's disease.

Reed-Sternberg cell: survival in a hostile sea.

In contrast to the non-Hodgkin's lymphomas, little is known regarding the origin, genetics, and function of the Reed-Sternberg cell of Hodgkin's disease. Unlike other cancers, the neoplastic cell of Hodgkin's disease, the Reed-Sternberg cell, is vastly outnumbered by a surrounding intense inflammatory infiltrate. How this rare neoplastic cell originates, persists, and disseminates in a presumably hostile cellular environment has remained a mystery. Understanding the biology of the Reed-Sternberg cell has been impeded by the rarity of the cell in tumor tissue. Herein, we describe how the application of single-cell genetic analysis has revealed a clonal and, possibly, germinal center B-cell origin of the Reed-Sternberg cell. By phenotype and function, Reed-Sternberg cells are highly interactive with their cellular microenvironment through cell-cell adhesion, expression of members of the tumor necrosis factor receptor superfamily, and elaboration of cytokines. Perhaps by their mimicry of immune system cells with antigen-presenting function, Reed-Sternberg cells mediate the unusual clinical and pathologic features of Hodgkin's disease: intense tissue inflammatory infiltrate, fibrosis, and constitutional symptoms.

Rearrangement, hypermutation, and possible preferential use of a VH5 gene, VH32, in a Hodgkin's cell line.

Nonrandom use of immunoglobulin variable (V) gene segments is a feature of some B-cell neoplasms, possibly as a consequence of antigen selection. In Hodgkin's disease, the primary tissues, cell lines, and even single Reed-Sternberg cells can carry immunoglobulin gene rearrangements. Here, we examined the immunoglobulin heavy-chain genes of a well-characterized Hodgkin's-derived cell line, L428, and found a hypermutated VH32 gene involving a conventional V(N)D(N)J4-C gamma 4 rearrangement. VH32 is one of two rearranging members of the VH5 family that is also rearranged preferentially in some B-cell neoplasms and familial CLL. Unexpectedly, the closest known rearranged sequence match for the rearranged VH gene of L428 was found in the single Reed-Sternberg cells of lymphocyte-predominance Hodgkin's disease, and is a mutated VH251, the only other rearranging member of the VH5 family. Assuming random usage of the human VH pool, the chance of coincident VH5 family gene rearrangement in the two cases of Hodgkin's disease is only about 10(-3). Biased use of VH genes suggests a B-cell target that is either selected by antigen or vulnerable to transformation at an early antigen-independent, developmental stage. These findings raise the question whether similar processes operate in Hodgkin's disease.