Olivier Van Wuytswinkel scite author profile

Quantitative RT-PCR (reverse transcription polymerase chain reaction, also known as qRT-PCR or real-time RT-PCR) has been used in large proportions of transcriptome analyses published to date. The accuracy of the results obtained by this method strongly depends on accurate transcript normalization using stably expressed genes, known as references. Statistical algorithms have been developed recently to help validate reference genes but, surprisingly, this robust approach is under-utilized in plants. Instead, putative 'housekeeping' genes tend to be used as references without any proper validation. The concept of normalization in transcript quantification is introduced here and the factors affecting its reliability in qRT-PCR are discussed in an attempt to convince molecular biologists, and non-specialists, that systematic validation of reference genes is essential for producing accurate, reliable data in qRT-PCR analyses, and thus should be an integral component of them.

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Combined networks regulating seed maturation

Gutierrez

Wuytswinkel

Castelain

et al. 2007

Trends in Plant Science

298

230

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Towards a Systematic Validation of References in Real-Time RT-PCR

et al. 2008

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Cellular and molecular aspects of iron metabolism in plants

Briat¹,

Fobis-Loisy²,

Grignon³

et al. 1995

Biology of the Cell

210

121

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Iron is an essential element for plant metabolism because of its redox properties. Its long distance and intracellular trafficking require specialized proteins and low molecular mass chelates because of its insolubility and toxicity in presence of oxygen. Iron deficiency induces various morphological and biochemical changes. They include root hair morphogenesis, differentiation of rhizoder-ma1 cells into transfer cells, yellowing of leaves and ultrastructural disorganisation of chloroplasts and mitochondria, as well as increased synthesis of organic acids and phenolics, and activation of root systems responsible for an enhanced iron uptake capacity. Upon iron resupply, these alterations disappeared within few days and a transient accumulation of the iron storage protein ferritin in the plastids is one of the early events in this process. Iron excess can also occur in plants where it elicits an oxidative stress leading to necrotic spots in the leaves. Induction of ferritin synthesis is again an early event of the plant response to this iron toxicity. Plant hormones such as auxin, abscisic acid and ethylene, as well as reactive oxygen intermediates play an important role in the transduction pathways, allowing plants to respond to these iron-deficiency and excess stresses. Similarities and differences among the various mechanisms responsible for iron uptake and storage in mammals, higher plants and yeast are outlined. Relationships between iron and copper metabolism are also indicated. plant / root / chloroplast / iron / ferritinIron traffk in non-stressed plants

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