Priyanka Agarwal

Publications

• 3.56

  Impact points

  MicroRNAs in diabetes: tiny players in big disease.

  Amit K Pandey, Priyanka Agarwal, Kirandeep Kaur, Malabika Datta

  Cellular physiology and biochemistry : international journal of experimental cellular physiology, biochemistry, and pharmacology. 02/2009; 23(4-6):221-32.

  MicroRNAs (miRNAs) are a novel group of universally present small non-coding RNAs that have been implicated in wide ranging physiological processes and thereby are critical in the manifestation of diverse diseases. Since their discovery as developmental regulators in C.elegans, they have come a long... [more] MicroRNAs (miRNAs) are a novel group of universally present small non-coding RNAs that have been implicated in wide ranging physiological processes and thereby are critical in the manifestation of diverse diseases. Since their discovery as developmental regulators in C.elegans, they have come a long way and are currently associated with normal and diverse pathophysiological states including Parkinson's syndrome, cardiac hypertrophy, viral infection, diabetes and several types of cancer. Of special significance is their involvement in diabetes, an area in which several emerging reports point to the fact that these small RNA species could be special and critical in this complex disease and they or their specific inhibitors may be exploited as targets for therapeutic intervention. The stable nature of these miRNAs over mRNAs is an added advantage of them being projected for the same. This review focuses on and discusses the current diabetic epidemic and the potential role(s) of these miRNAs in various physiological processes that lead to the diabetic phenotype with an objective of better understanding the emerging mechanisms of these small molecules in the development and progression of diabetes and its complications.

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• 4.41

  Impact points

  Glucose and auxin signaling interaction in controlling Arabidopsis thaliana seedlings root growth and development.

  Bhuwaneshwar S Mishra, Manjul Singh, Priyanka Aggrawal, Ashverya Laxmi

  PLoS ONE. 02/2009; 4(2):e4502.

  BACKGROUND: Plant root growth and development is highly plastic and can adapt to many environmental conditions. Sugar signaling has been shown to affect root growth and development by interacting with phytohormones such as gibberellins, cytokinin and abscisic acid. Auxin signaling and transport has ... [more] BACKGROUND: Plant root growth and development is highly plastic and can adapt to many environmental conditions. Sugar signaling has been shown to affect root growth and development by interacting with phytohormones such as gibberellins, cytokinin and abscisic acid. Auxin signaling and transport has been earlier shown to be controlling plant root length, number of lateral roots, root hair and root growth direction. PRINCIPAL FINDINGS: Increasing concentration of glucose not only controls root length, root hair and number of lateral roots but can also modulate root growth direction. Since root growth and development is also controlled by auxin, whole genome transcript profiling was done to find out the extent of interaction between glucose and auxin response pathways. Glucose alone could transcriptionally regulate 376 (62%) genes out of 604 genes affected by IAA. Presence of glucose could also modulate the extent of regulation 2 fold or more of almost 63% genes induced or repressed by IAA. Interestingly, glucose could affect induction or repression of IAA affected genes (35%) even if glucose alone had no significant effect on the transcription of these genes itself. Glucose could affect auxin biosynthetic YUCCA genes family members, auxin transporter PIN proteins, receptor TIR1 and members of a number of gene families including AUX/IAA, GH3 and SAUR involved in auxin signaling. Arabidopsis auxin receptor tir1 and response mutants, axr2, axr3 and slr1 not only display a defect in glucose induced change in root length, root hair elongation and lateral root production but also accentuate glucose induced increase in root growth randomization from vertical suggesting glucose effects on plant root growth and development are mediated by auxin signaling components. CONCLUSION: Our findings implicate an important role of the glucose interacting with auxin signaling and transport machinery to control seedling root growth and development in changing nutrient conditions.