Análisis molecular de la longitud telomérica en linfomas foliculares: Su participación en la progresón tumoral / Molecular analysis of telomere length in follicular lymphomas: Its participation in tumor progression

Los telómeros son estructuras esenciales para el mantenimiento de la integridad cromosómica y la capacidad replicativa de la célula. La reducción de la longitud telomérica (LT) aumenta la probabilidad de producir errores capaces de generar cambios genómicos importantes para el desarrollo neoplásico, determinando desbalances de material genético. En este trabajo se evaluó la LT mediante el análisis de fragmentos de restricción terminal (TRF) en médula ósea y/o biopsia ganglionar de 36 pacientes (edad media: 54.2 años; rango 29-77 años; 21 varones): 29 con linfoma folicular (LF) al diagnóstico y 7 con linfoma B difuso a células grandes secundario a LF (LBDCG-S). Se efectuó el análisis del rearreglo molecular del gen BCL-2 por PCR anidada y de larga distancia. Las medias de TRF en LF (4.18±0.18 Kb) y LBDCG-S (3.31±0.25 Kb) resultaron significativamente menores que en controles (8.50±0.50 Kb) (p<0.001), encontrándose diferencias entre ambos subtipos histológicos (p=0.036). Las muestras negativas para el rearreglo BCL-2 mostraron LT menores (3.39±0.30 Kb) que las positivas (4.25±0.19 Kb) (p=0.023), observándose una tendencia a valores menores en pacientes negativos para el rearreglo BCL-2, intermedios en positivos para mcr, minor cluster region, (3.84±0.45 Kb) y mayores en los positivos para MBR, Major Breakpoint Region, (4.35±0.21 Kb). Nuestros resultados muestran una reducción de la LT en LF y LBDCG-S, con TRFs significativamente más cortos en estos últimos, sugiriendo la participación del acortamiento telomérico em la progresión tumoral. Asimismo, las diferencias detectadas entre los casos BCL-2 positivos y negativos sustentarían la presencia de diferentes mecanismos patogénicos propuestos para estos distintos LF. (AU)

Análisis molecular de la longitud telomérica en linfomas foliculares: Su participación en la progresón tumoral / Molecular analysis of telomere length in follicular lymphomas: Its participation in tumor progression

Los telómeros son estructuras esenciales para el mantenimiento de la integridad cromosómica y la capacidad replicativa de la célula. La reducción de la longitud telomérica (LT) aumenta la probabilidad de producir errores capaces de generar cambios genómicos importantes para el desarrollo neoplásico, determinando desbalances de material genético. En este trabajo se evaluó la LT mediante el análisis de fragmentos de restricción terminal (TRF) en médula ósea y/o biopsia ganglionar de 36 pacientes (edad media: 54.2 años; rango 29-77 años; 21 varones): 29 con linfoma folicular (LF) al diagnóstico y 7 con linfoma B difuso a células grandes secundario a LF (LBDCG-S). Se efectuó el análisis del rearreglo molecular del gen BCL-2 por PCR anidada y de larga distancia. Las medias de TRF en LF (4.18±0.18 Kb) y LBDCG-S (3.31±0.25 Kb) resultaron significativamente menores que en controles (8.50±0.50 Kb) (p<0.001), encontrándose diferencias entre ambos subtipos histológicos (p=0.036). Las muestras negativas para el rearreglo BCL-2 mostraron LT menores (3.39±0.30 Kb) que las positivas (4.25±0.19 Kb) (p=0.023), observándose una tendencia a valores menores en pacientes negativos para el rearreglo BCL-2, intermedios en positivos para mcr, minor cluster region, (3.84±0.45 Kb) y mayores en los positivos para MBR, Major Breakpoint Region, (4.35±0.21 Kb). Nuestros resultados muestran una reducción de la LT en LF y LBDCG-S, con TRFs significativamente más cortos en estos últimos, sugiriendo la participación del acortamiento telomérico em la progresión tumoral. Asimismo, las diferencias detectadas entre los casos BCL-2 positivos y negativos sustentarían la presencia de diferentes mecanismos patogénicos propuestos para estos distintos LF.

[Telomeres and telomerase activity: their role in aging and in neoplastic development]. / Telómeros y actividad de telomerasa: su participación en el envejecimiento y el desarrollo neoplásico.

Telomeres are specialized structures at the ends of eukaryotic chromosomes, composed of tandem repeats of a repetitive DNA sequence (TTAGGG)n and associated proteins. They have a number of important functions including the protection of chromosomes from end-to-end fusion and degradation. When telomeres become critically short, telomere separation in mitosis cannot be performed properly leading to metaphase telomeric associations (tas) and chromosome instability. This instability can be relevant for neoplastic transformation because it increases the probability of errors that can generate genetic changes critical in the multistep process of transformation, like gene amplification and loss of heterozygosity. The mechanisms involved in tas are unknown, but it could be because of failure in the enzymatic activity of telomerase, a ribonucleoprotein enzyme with an RNA template that directs synthesis of telomeric repeats at chromosome extremities, producing telomeric length stabilization. A progressive telomere shortening with ageing has been shown to occur both in vitro and in vivo. Recent studies have shown an association between the presence of tas and telomeric shortening, and also a correlation between telomere reduction and increased telomerase activity in both solid tumors and hematologic malignancies. The evidence that most human malignancies have telomerase activity would indicate that telomerase could be a prevalent and specific tumor marker, and thus may be a novel and excellent target for anti-cancer therapy.

Telómeros y actividad de telomerasa: su participación en el envejecimiento y el desarrollo neoplásico. / [Telomeres and telomerase activity: their role in aging and in neoplastic development]

Telomeres are specialized structures at the ends of eukaryotic chromosomes, composed of tandem repeats of a repetitive DNA sequence (TTAGGG)n and associated proteins. They have a number of important functions including the protection of chromosomes from end-to-end fusion and degradation. When telomeres become critically short, telomere separation in mitosis cannot be performed properly leading to metaphase telomeric associations (tas) and chromosome instability. This instability can be relevant for neoplastic transformation because it increases the probability of errors that can generate genetic changes critical in the multistep process of transformation, like gene amplification and loss of heterozygosity. The mechanisms involved in tas are unknown, but it could be because of failure in the enzymatic activity of telomerase, a ribonucleoprotein enzyme with an RNA template that directs synthesis of telomeric repeats at chromosome extremities, producing telomeric length stabilization. A progressive telomere shortening with ageing has been shown to occur both in vitro and in vivo. Recent studies have shown an association between the presence of tas and telomeric shortening, and also a correlation between telomere reduction and increased telomerase activity in both solid tumors and hematologic malignancies. The evidence that most human malignancies have telomerase activity would indicate that telomerase could be a prevalent and specific tumor marker, and thus may be a novel and excellent target for anti-cancer therapy.

Evidence of chromosome instability in chronic pancreatitis.

In the current study we analyzed chromosome instability on peripheral blood lymphocytes cultured from 7 untreated patients with chronic pancreatitis (CP) by assessing telomeric associations (TAS), chromosome aberrations (CA) and sister chromatid exchanges (SCE). Seven healthy individuals were also analyzed. Mean frequencies of TAS were significantly higher in CP patients (X +/- SE: 11.00 +/- 2.37) compared to controls (1.00 +/- 0.30) (p<0.001). Chromosomes preferentially involved in TAS were: 9, 20, 16 and 21, being the most affected arms: 9p, 20q, 16p, 9q and 21q. All these terminal bands were coincident with cancer breakpoints (p<0.03), two of them (40%) were specifically associated to pancreatic carcinoma rearrangements. Three bands (60%) were coincident with oncogene location. The mean frequency of CA was significantly higher in patients (3.88 +/- 0.80) compared to controls (0.63 +/- 0.49) (p<0.001). Chromosomes 1, 2 and 13 were the most damaged. No specifically affected breakpoints were found. SCE analysis showed higher levels in patients (8.33 +/- 0.70) than in controls (6.62 +/- 0.34) (p<0.025), but no differences were observed in cell cycle kinetics. Our results clearly indicate that CP patients exhibit chromosome instability, showing the presence of an unstable genome that could be related to the cancer development observed in this disease.